Blunt splenic trauma.

The treatment of blunt splenic injury has evolved over time from splenectomy in all patients to nonoperative management in stable patients with operation reserved for failures of NOM. While rates of OPSI remain low in trauma patients, splenic salvage in stable patients should be attempted. However, clinical evidence of ongoing blood loss or instability should be addressed with prompt splenectomy. Careful patient selection is of paramount importance in nonoperative management of blunt splenic injury.

Hematopoietic failure after hemorrhagic shock is mediated partially through mesenteric lymph.

OBJECTIVE: To determine whether hemorrhagic shock-induced bone marrow failure is mediated by the gut through the production of toxic mesenteric lymph and whether shock-induced bone marrow failure could be prevented by division of the mesenteric lymphatics. DESIGN: Prospective, controlled study. SETTING: University surgical research laboratory. SUBJECTS: Male Sprague-Dawley rats. INTERVENTIONS: Rats were divided into five groups: unmanipulated controls (n = 12), hemorrhagic shock with laparotomy (n = 8), hemorrhagic shock with mesenteric lymph duct ligation (n = 10), sham shock with laparotomy (n = 6), and sham shock with mesenteric lymph duct ligation (n = 7). At either 3 or 6 hrs after resuscitation, bone marrow was obtained for determination of early (cobblestone forming cells) and late (granulocyte-macrophage colony forming unit and erythroid burst forming unit) hematopoietic progenitor cell growth. Parallel cultures were plated with plasma (1% and 2% v/v) from all groups to determine the effect of lymphatic ligation on hematopoiesis. MEASUREMENTS AND MAIN RESULTS: Bone marrow cellularity, cobblestone forming cells, granulocyte-macrophage colony forming unit, and erythroid burst forming unit growth in rats subjected to hemorrhagic with lymph duct ligation were similar to those observed in sham-treated animals and significantly greater than in rats subjected to shock and laparotomy without lymphatic duct ligation. Plasma from rats subjected to shock without lymph ligation was inhibitory to hematopoietic progenitor cell growth. In contrast, this shock-induced inhibition was not observed with plasma obtained from shocked rats that underwent mesenteric lymph ligation. CONCLUSIONS: Hemorrhagic shock suppresses bone marrow hematopoiesis as measured by a decrease in early and late progenitor cell growth. This suppression appears mediated through mesenteric lymph as the effect is abrogated by mesenteric lymph duct ligation. These data clearly demonstrate a link between the gut and bone marrow failure after hemorrhagic shock

Injury-enhanced calcium mobilization in circulating rat neutrophils models human PMN responses.

G-protein coupled (GPC) chemoattractants are important neutrophil (PMN) activators in human shock and sepsis, acting in part by increasing cytosolic calcium ([Ca2+]i). Rats are widely used as laboratory models of shock and sepsis, but reports of [Ca2+]i flux in circulating rat PMN are rare. Moreover, the [Ca2+]i values reported often differ markedly from human systems. We developed study methods where basal [Ca2+]i values in circulating rat PMN were comparable to human PMN, but rat PMN still mobilized calcium poorly after stimulation. Trauma (laparotomy) did not change rat PMN basal [Ca2+]i, but induced brisk [Ca2+]i responses to chemokine and lipid mediators that approximated human PMN responses. This was associated with marked loading of microsomal calcium stores. Formyl peptides still mobilized calcium less well in rat than human PMN. Normal rat PMN appear to circulate in a less mature or primed form than human PMN. A very limited injury rapidly converts rat PMN to a more activated phenotype. PMN thus activated act quite similar to human PMN in terms of GPC receptor-mediated calcium mobilization. Trauma enhances rat PMN responses to GPC agonists at least in part by loading cell calcium stores.